RFC 1349 – Type of Service in the Internet Protocol Suite

Network Working Group P. Almquist
Request for Comments: 1349 Consultant
Updates: RFCs 1248, 1247, 1195, July 1992
1123, 1122, 1060, 791
Type of Service in the Internet Protocol Suite
Status of This Memo
This document specifies an IAB standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "IAB
Official Protocol Standards" for the standardization state and status
of this protocol. Distribution of this memo is unlimited.
Summary
This memo changes and clarifies some aspects of the semantics of the
Type of Service octet in the Internet Protocol (IP) header. The
handling of IP Type of Service by both hosts and routers is specified
in some detail.
This memo defines a new TOS value for requesting that the network
minimize the monetary cost of transmitting a datagram. A number of
additional new TOS values are reserved for future experimentation and
standardization. The ability to request that transmission be
optimized along multiple axes (previously accomplished by setting
multiple TOS bits simultaneously) is removed. Thus, for example, a
single datagram can no longer request that the network simultaneously
minimize delay and maximize throughput.
In addition, there is a minor conflict between the Host Requirements
(RFC-1122 and RFC-1123) and a number of other standards concerning
the sizes of the fields in the Type of Service octet. This memo
resolves that conflict.
Table of Contents
1. Introduction ............................................... 3
2. Goals and Philosophy ....................................... 3
3. Specification of the Type of Service Octet ................. 4
4. Specification of the TOS Field ............................. 5
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5. Use of the TOS Field in the Internet Protocols ............. 6
5.1 Internet Control Message Protocol (ICMP) ............... 6
5.2 Transport Protocols .................................... 7
5.3 Application Protocols .................................. 7
6. ICMP and the TOS Facility .................................. 8
6.1 Destination Unreachable ................................ 8
6.2 Redirect ............................................... 9
7. Use of the TOS Field in Routing ............................ 9
7.1 Host Routing ........................................... 10
7.2 Forwarding ............................................. 12
8. Other consequences of TOS .................................. 13
APPENDIX A. Updates to Other Specifications ................... 14
A.1 RFC-792 (ICMP) ......................................... 14
A.2 RFC-1060 (Assigned Numbers) ............................ 14
A.3 RFC-1122 and RFC-1123 (Host Requirements) .............. 16
A.4 RFC-1195 (Integrated IS-IS) ............................ 16
A.5 RFC-1247 (OSPF) and RFC-1248 (OSPF MIB) ................ 17
APPENDIX B. Rationale ......................................... 18
B.1 The Minimize Monetary Cost TOS Value ................... 18
B.2 The Specification of the TOS Field ..................... 19
B.3 The Choice of Weak TOS Routing ......................... 21
B.4 The Retention of Longest Match Routing ................. 22
B.5 The Use of Destination Unreachable ..................... 23
APPENDIX C. Limitations of the TOS Mechanism .................. 24
C.1 Inherent Limitations ................................... 24
C.2 Limitations of this Specification ...................... 25
References ..................................................... 27
Acknowledgements ............................................... 28
Security Considerations ........................................ 28
Author's Address ............................................... 28
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1. Introduction
Paths through the Internet vary widely in the quality of service they
provide. Some paths are more reliable than others. Some impose high
call setup or per-packet charges, while others do not do usage-based
charging. Throughput and delay also vary widely. Often there are
tradeoffs: the path that provides the highest throughput may well not
be the one that provides the lowest delay or the lowest monetary
cost. Therefore, the "optimal" path for a packet to follow through
the Internet may depend on the needs of the application and its user.
Because the Internet itself has no direct knowledge of how to
optimize the path for a particular application or user, the IP
protocol [11] provides a (rather limited) facility for upper layer
protocols to convey hints to the Internet Layer about how the
tradeoffs should be made for the particular packet. This facility is
the "Type of Service" facility, abbreviated as the "TOS facility" in
this memo.
Although the TOS facility has been a part of the IP specification
since the beginning, it has been little used in the past. However,
the Internet host specification [1,2] now mandates that hosts use the
TOS facility. Additionally, routing protocols (including OSPF [10]
and Integrated IS-IS [7]) have been developed which can compute
routes separately for each type of service. These new routing
protocols make it practical for routers to consider the requested
type of service when making routing decisions.
This specification defines in detail how hosts and routers use the
TOS facility. Section 2 introduces the primary considerations that
motivated the design choices in this specification. Sections 3 and 4
describe the Type of Service octet in the IP header and the values
which the TOS field of that octet may contain. Section 5 describes
how a host (or router) chooses appropriate values to insert into the
TOS fields of the IP datagrams it originates. Sections 6 and 7
describe the ICMP Destination Unreachable and Redirect messages and
how TOS affects path choice by both hosts and routers. Section 8
describes some additional ways in which TOS may optionally affect
packet processing. Appendix A describes how this specification
updates a number of existing specifications. Appendices B and C
expand on the discussion in Section 2.
2. Goals and Philosophy
The fundamental rule that guided this specification is that a host
should never be penalized for using the TOS facility. If a host
makes appropriate use of the TOS facility, its network service should
be at least as good as (and hopefully better than) it would have been
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if the host had not used the facility. This goal was considered
particularly important because it is unlikely that any specification
which did not meet this goal, no matter how good it might be in other
respects, would ever become widely deployed and used. A particular
consequence of this goal is that if a network cannot provide the TOS
requested in a packet, the network does not discard the packet but
instead delivers it the same way it would have been delivered had
none of the TOS bits been set.
Even though the TOS facility has not been widely used in the past, it
is a goal of this memo to be as compatible as possible with existing
practice. Primarily this means that existing host implementations
should not interact badly with hosts and routers which implement the
specifications of this memo, since TOS support is almost non-existent
in routers which predate this specification. However, this memo does
attempt to be compatible with the treatment of IP TOS in OSPF and
Integrated IS-IS.
Because the Internet community does not have much experience with
TOS, it is important that this specification allow easy definition
and deployment of new and experimental types of service. This goal
has had a significant impact on this specification. In particular,
it led to the decision to fix permanently the size of the TOS field
and to the decision that hosts and routers should be able to handle a
new type of service correctly without having to understand its
semantics.
Appendix B of this memo provides a more detailed explanation of the
rationale behind particular aspects of this specification.
3. Specification of the Type of Service Octet
The TOS facility is one of the features of the Type of Service octet
in the IP datagram header. The Type of Service octet consists of
three fields:
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| | | |
| PRECEDENCE | TOS | MBZ |
| | | |
+-----+-----+-----+-----+-----+-----+-----+-----+
The first field, labeled "PRECEDENCE" above, is intended to denote
the importance or priority of the datagram. This field is not
discussed in detail in this memo.
The second field, labeled "TOS" above, denotes how the network should
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make tradeoffs between throughput, delay, reliability, and cost. The
TOS field is the primary topic of this memo.
The last field, labeled "MBZ" (for "must be zero") above, is
currently unused. The originator of a datagram sets this field to
zero (unless participating in an Internet protocol experiment which
makes use of that bit). Routers and recipients of datagrams ignore
the value of this field. This field is copied on fragmentation.
In the past there has been some confusion about the size of the TOS
field. RFC-791 defined it as a three bit field, including bits 3-5
in the figure above. It included bit 6 in the MBZ field. RFC-1122
added bits 6 and 7 to the TOS field, eliminating the MBZ field. This
memo redefines the TOS field to be the four bits shown in the figure
above. The reasons for choosing to make the TOS field four bits wide
can be found in Appendix B.2.
4. Specification of the TOS Field
As was stated just above, this memo redefines the TOS field as a four
bit field. Also contrary to RFC-791, this memo defines the TOS field
as a single enumerated value rather than as a set of bits (where each
bit has its own meaning). This memo defines the semantics of the
following TOS field values (expressed as binary numbers):
1000 -- minimize delay
0100 -- maximize throughput
0010 -- maximize reliability
0001 -- minimize monetary cost
0000 -- normal service
The values used in the TOS field are referred to in this memo as "TOS
values", and the value of the TOS field of an IP packet is referred
to in this memo as the "requested TOS". The TOS field value 0000 is
referred to in this memo as the "default TOS."
Because this specification redefines TOS values to be integers rather
than sets of bits, computing the logical OR of two TOS values is no
longer meaningful. For example, it would be a serious error for a
router to choose a low delay path for a packet whose requested TOS
was 1110 simply because the router noted that the former "delay bit"
was set.
Although the semantics of values other than the five listed above are
not defined by this memo, they are perfectly legal TOS values, and
hosts and routers must not preclude their use in any way. As will
become clear after reading the remainder of this memo, only the
default TOS is in any way special. A host or router need not (and
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except as described in Section 8 should not) make any distinction
between TOS values whose semantics are defined by this memo and those
that are not.
It is important to note the use of the words "minimize" and
"maximize" in the definitions of values for the TOS field. For
example, setting the TOS field to 1000 (minimize delay) does not
guarantee that the path taken by the datagram will have a delay that
the user considers "low". The network will attempt to choose the
lowest delay path available, based on its (often imperfect)
information about path delay. The network will not discard the
datagram simply because it believes that the delay of the available
paths is "too high" (actually, the network manager can override this
behavior through creative use of routing metrics, but this is
strongly discouraged: setting the TOS field is intended to give
better service when it is available, rather than to deny service when
it is not).
5. Use of the TOS Field in the Internet Protocols
For the TOS facility to be useful, the TOS fields in IP packets must
be filled in with reasonable values. This section discusses how
protocols above IP choose appropriate values.
5.1 Internet Control Message Protocol (ICMP)
ICMP [8,9,12] defines a number of messages for performing error
reporting and diagnostic functions for the Internet Layer. This
section describes how a host or router chooses appropriate TOS
values for ICMP messages it originates. The TOS facility also
affects the origination and processing of ICMP Redirects and ICMP
Destination Unreachables, but that is the topic of Section 6.
For purposes of this discussion, it is useful to divide ICMP
messages into three classes:
o ICMP error messages include ICMP message types 3 (Destination
Unreachable), 4 (Source Quench), 5 (Redirect), 11 (Time
Exceeded), and 12 (Parameter Problem).
o ICMP request messages include ICMP message types 8 (Echo), 10
(Router Solicitation), 13 (Timestamp), 15 (Information
Request -- now obsolete), and 17 (Address Mask Request).
o ICMP reply messages include ICMP message types 0 (Echo
Reply), 9 (Router Advertisement), 14 (Timestamp Reply), 16
(Information Reply -- also obsolete), and 18 (Address Mask
Reply).
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An ICMP error message is always sent with the default TOS (0000).
An ICMP request message may be sent with any value in the TOS
field. A mechanism to allow the user to specify the TOS value to
be used would be a useful feature in many applications that
generate ICMP request messages.
An ICMP reply message is sent with the same value in the TOS field
as was used in the corresponding ICMP request message.
5.2 Transport Protocols
When sending a datagram, a transport protocol uses the TOS
requested by the application. There is no requirement that both
ends of a transport connection use the same TOS. For example, the
sending side of a bulk data transfer application should request
that throughput be maximized, whereas the receiving side might
request that delay be minimized (assuming that it is primarily
sending small acknowledgement packets). It may be useful for a
transport protocol to provide applications with a mechanism for
learning the value of the TOS field that accompanied the most
recently received data.
It is quite permissible to switch to a different TOS in the middle
of a connection if the nature of the traffic being generated
changes. An example of this would be SMTP, which spends part of
its time doing bulk data transfer and part of its time exchanging
short command messages and responses.
TCP [13] should use the same TOS for datagrams containing only TCP
control information as it does for datagrams which contain user
data. Although it might seem intuitively correct to always
request that the network minimize delay for segments containing
acknowledgements but no data, doing so could corrupt TCP's round
trip time estimates.
5.3 Application Protocols
Applications are responsible for choosing appropriate TOS values
for any traffic they originate. The Assigned Numbers document
[15] lists the TOS values to be used by a number of common network
applications. For other applications, it is the responsibility of
the application's designer or programmer to make a suitable
choice, based on the nature of the traffic to be originated by the
application.
It is essential for many sorts of network diagnostic applications,
and desirable for other applications, that the user of the
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application be able to override the TOS value(s) which the
application would otherwise choose.
The Assigned Numbers document is revised and reissued
periodically. Until RFC-1060, the edition current as this is
being written, has been superceded, readers should consult
Appendix A.2 of this memo.
6. ICMP and the TOS Facility
Routers communicate routing information to hosts using the ICMP
protocol [12]. This section describes how support for the TOS
facility affects the origination and interpretation of ICMP Redirect
messages and certain types of ICMP Destination Unreachable messages.
This memo does not define any new extensions to the ICMP protocol.
6.1 Destination Unreachable
The ICMP Destination Unreachable message contains a code which
describes the reason that the destination is unreachable. There
are four codes [1,12] which are particularly relevant to the topic
of this memo:
0 -- network unreachable
1 -- host unreachable
11 -- network unreachable for type of service
12 -- host unreachable for type of service
A router generates a code 11 or code 12 Destination Unreachable
when an unreachable destination (network or host) would have been
reachable had a different TOS value been specified. A router
generates a code 0 or code 1 Destination Unreachable in other
cases.
A host receiving a Destination Unreachable message containing any
of these codes should recognize that it may result from a routing
transient. The host should therefore interpret the message as
only a hint, not proof, that the specified destination is
unreachable.
The use of codes 11 and 12 may seem contrary to the statement in
Section 2 that packets should not be discarded simply because the
requested TOS cannot be provided. The rationale for having these
codes and the limited cases in which they are expected to be used
are described in Appendix B.5.
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6.2 Redirect
The ICMP Redirect message also includes a code, which specifies
the class of datagrams to which the Redirect applies. There are
currently four codes defined:
0 -- redirect datagrams for the network
1 -- redirect datagrams for the host
2 -- redirect datagrams for the type of service and network
3 -- redirect datagrams for the type of service and host
A router generates a code 3 Redirect when the Redirect applies
only to IP packets which request a particular TOS value. A router
generates a code 1 Redirect instead when the the optimal next hop
on the path to the destination would be the same for any TOS
value. In order to minimize the potential for host confusion,
routers should refrain from using codes 0 and 2 in Redirects
[3,6].
Although the current Internet Host specification [1] only requires
hosts to correctly handle code 0 and code 1 Redirects, a host
should also correctly handle code 2 and code 3 Redirects, as
described in Section 7.1 of this memo. If a host does not, it is
better for the host to treat code 2 as equivalent to code 0 and
code 3 as equivalent to code 1 than for the host to simply ignore
code 2 and code 3 Redirects.
7. Use of the TOS Field in Routing
Both hosts and routers should consider the value of the TOS field of
a datagram when choosing an appropriate path to get the datagram to
its destination. The mechanisms for doing so are discussed in this
section.
Whether a packet's TOS value actually affects the path it takes
inside of a particular routing domain is a choice made by the routing
domain's network manager. In many routing domains the paths are
sufficiently homogeneous in nature that there is no reason for
routers to choose different paths based up the TOS field in a
datagram. Inside such a routing domain, the network manager may
choose to limit the size of the routing database and of routing
protocol updates by only defining routes for the default (0000) TOS.
Neither hosts nor routers should need to have any explicit knowledge
of whether TOS affects routing in the local routing domain.
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7.1 Host Routing
When a host (which is not also a router) wishes to send an IP
packet to a destination on another network or subnet, it needs to
choose an appropriate router to send the packet to. According to
the IP Architecture, it does so by maintaining a route cache and a
list of default routers. Each entry in the route cache lists a
destination (IP address) and the appropriate router to use to
reach that destination. The host learns the information stored in
its route cache through the ICMP Redirect mechanism. The host
learns the list of default routers either from static
configuration information or by using the ICMP Router Discovery
mechanism [8]. When the host wishes to send an IP packet, it
searches its route cache for a route matching the destination
address in the packet. If one is found it is used; if not, the
packet is sent to one of the default routers. All of this is
described in greater detail in section 3.3.1 of RFC-1122 [1].
Adding support for the TOS facility changes the host routing
procedure only slightly. In the following, it is assumed that (in
accordance with the current Internet Host specification [1]) the
host treats code 0 (redirect datagrams for the network) Redirects
as if they were code 1 (redirect datagrams for the host)
Redirects. Similarly, it is assumed that the host treats code 2
(redirect datagrams for the network and type of service) Redirects
as if they were code 3 (redirect datagrams for the host and type
of service) Redirects. Readers considering violating these
assumptions should be aware that long and careful consideration of
the way in which Redirects are treated is necessary to avoid
situations where every packet sent to some destination provokes a
Redirect. Because these assumptions match the recommendations of
Internet Host specification, that careful consideration is beyond
the scope of this memo.
As was described in Section 6.2, some ICMP Redirects apply only to
IP packets which request a particular TOS. Thus, a host (at least
conceptually) needs to store two types of entries in its route
cache:
type 1: { destination, TOS, router }
type 2: { destination, *, router }
where type 1 entries result from the receipt of code 3 (or code 1)
Redirects and type 2 entries result from the receipt of code 2 (or
code 0) Redirects.
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When a host wants to send a packet, it first searches the route
cache for a type 1 entry whose destination matches the destination
address of the packet and whose TOS matches the requested TOS in
the packet. If it doesn't find one, the host searches its route
cache again, this time looking for a type 2 entry whose
destination matches the destination address of the packet. If
either of these searches finds a matching entry, the packet is
sent to the router listed in the matching entry. Otherwise, the
packet is sent to one of the routers on the list of default
routers.
When a host creates (or updates) a type 2 entry, it must flush
from its route cache any type 1 entries which have the same
destination. This is necessary for correctness, since the type 1
entry may be obsolete but would continue to be used if it weren't
flushed because type 1 entries are always preferred over type 2
entries.
However, the converse is not true: when a host creates a type 1
entry, it should not flush a type 2 entry that has the same
destination. In this case, the type 1 entry will properly
override the type 2 entry for packets whose destination address
and requested TOS match the type 1 entry. Because the type 2
entry may well specify the correct router for some TOS values
other than the one specified in the type 1 entry, saving the type
2 entry will likely cut down on the number of Redirects which the
host would otherwise receive. This savings can potentially be
substantial if one of the Redirects which was avoided would have
created a new type 2 entry (thereby causing the new type 1 entry
to be flushed). That can happen, for example, if only some of the
routers on the local net are part of a routing domain that
computes separate routes for each TOS.
As an alternative, a host may treat all Redirects as if they were
code 3 (redirect datagrams for hosts and type of service)
Redirects. This alternative allows the host to have only type 1
route cache entries, thereby simplifying route lookup and
eliminating the need for the rules in the previous two paragraphs.
The disadvantage of this approach is that it increases the size of
the route cache and the amount of Redirect traffic if the host
sends packets with a variety of requested TOS's to a destination
for which the host should use the same router regardless of the
requested TOS. There is not yet sufficient experience with the
TOS facility to know whether that disadvantage would be serious
enough in practice to outweigh the simplicity of this approach.
Despite RFC-1122, some hosts acquire their routing information by
"wiretapping" a routing protocol instead of by using the
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mechanisms described above. Such hosts will need to follow the
procedures described in Section 7.2 (except of course that hosts
will not send ICMP Destination Unreachables or ICMP Redirects).
7.2 Forwarding
A router in the Internet should be able to consider the value of
the TOS field when choosing an appropriate path over which to
forward an IP packet. How a router does this is a part of the
more general issue of how a router picks appropriate paths. This
larger issue can be extremely complex [4], and is beyond the scope
of this memo. This discussion should therefore be considered only
an overview. Implementors should consult the Router Requirements
specification [3] and the the specifications of the routing
protocols they implement for details.
A router associates a TOS value with each route in its forwarding
table. The value can be any of the possible values of the TOS
field in an IP datagram (including those values whose semantics
are yet to be defined). Any routes learned using routing
protocols which support TOS are assigned appropriate TOS value by
those protocols. Routes learned using other routing protocols are
always assigned the default TOS value (0000). Static routes have
their TOS values assigned by the network manager.
When a router wants to forward a packet, it first looks up the
destination address in its forwarding table. This yields a set of
candidate routes. The set may be empty (if the destination is
unreachable), or it may contain one or more routes to the
destination. If the set is not empty, the TOS values of the
routes in the set are examined. If the set contains a route whose
TOS exactly matches the TOS field of the packet being forwarded
then that route is chosen. If not but the set contains a route
with the default TOS then that route is chosen.
If no route is found, or if the the chosen route has an infinite
metric, the destination is considered to be unreachable. The
packet is discarded and an ICMP Destination Unreachable is
returned to the source. Normally, the Unreachable uses code 0
(Network unreachable) or 1 (Host unreachable). If, however, a
route to the destination exists which has a different TOS value
and a non-infinite metric then code 11 (Network unreachable for
type of service) or code 12 (Host unreachable for type of service)
must be used instead.
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8. Other consequences of TOS
The TOS field in a datagram primarily affects the path chosen through
the network, but an implementor may choose to have TOS also affect
other aspects of how the datagram is handled. For example, a host or
router might choose to give preferential queuing on network output
queues to datagrams which have requested that delay be minimized.
Similarly, a router forced by overload to discard packets might
attempt to avoid discarding packets that have requested that
reliability be maximized. At least one paper [14] has explored these
ideas in some detail, but little is known about how well such special
handling would work in practice.
Additionally, some Link Layer protocols have their own quality of
service mechanisms. When a router or host transmits an IP packet, it
might request from the Link Layer a quality of service as close as
possible to the one requested in the TOS field in the IP header.
Long ago an attempt (RFC-795) was made to codify how this might be
done, but that document describes Link Layer protocols which have
since become obsolete and no more recent document on the subject has
been written.
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APPENDIX A. Updates to Other Specifications
While this memo is primarily an update to the IP protocol
specification [11], it also peripherally affects a number of other
specifications. This appendix describes those peripheral effects.
This information is included in an appendix rather than in the main
body of the document because most if not all of these other
specifications will be updated in the future. As that happens, the
information included in this appendix will become obsolete.
A.1 RFC-792 (ICMP)
RFC-792 [12] defines a set of codes indicating reasons why a
destination is unreachable. This memo describes the use of two
additional codes:
11 -- network unreachable for type of service
12 -- host unreachable for type of service
These codes were defined in RFC-1122 [1] but were not included in
RFC-792.
A.2 RFC-1060 (Assigned Numbers)
RFC-1060 [15] describes the old interpretation of the TOS field
(as three independent bits, with no way to specify that monetary
cost should be minimized). Although it is likely obvious how the
values in RFC-1060 ought to be interpreted in light of this memo,
the information from that RFC is reproduced here. The only actual
changes are for ICMP (to conform to Section 5.1 of this memo) and
NNTP:
----- Type-of-Service Value -----
Protocol TOS Value
TELNET (1) 1000 (minimize delay)
FTP
Control 1000 (minimize delay)
Data (2) 0100 (maximize throughput)
TFTP 1000 (minimize delay)
SMTP (3)
Command phase 1000 (minimize delay)
DATA phase 0100 (maximize throughput)
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----- Type-of-Service Value -----
Protocol TOS Value
Domain Name Service
UDP Query 1000 (minimize delay)
TCP Query 0000
Zone Transfer 0100 (maximize throughput)
NNTP 0001 (minimize monetary cost)
ICMP
Errors 0000
Requests 0000 (4)
Responses (4)
Any IGP 0010 (maximize reliability)
EGP 0000
SNMP 0010 (maximize reliability)
BOOTP 0000
Notes:
(1) Includes all interactive user protocols (e.g., rlogin).
(2) Includes all bulk data transfer protocols (e.g., rcp).
(3) If the implementation does not support changing the TOS
during the lifetime of the connection, then the
recommended TOS on opening the connection is the default
TOS (0000).
(4) Although ICMP request messages are normally sent with the
default TOS, there are sometimes good reasons why they
would be sent with some other TOS value. An ICMP response
always uses the same TOS value as was used in the
corresponding ICMP request message. See Section 5.1 of
this memo.
An application may (at the request of the user) substitute 0001
(minimize monetary cost) for any of the above values.
This appendix is expected to be obsoleted by the next revision
of the Assigned Numbers document.
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A.3 RFC-1122 and RFC-1123 (Host Requirements)
The use of the TOS field by hosts is described in detail in
RFC-1122 [1] and RFC-1123 [2]. The information provided there is
still correct, except that:
(1) The TOS field is four bits wide rather than five bits wide.
The requirements that refer to the TOS field should refer
only to the four bits that make up the TOS field.
(2) An application may set bit 6 of the TOS octet to a non-zero
value (but still must not set bit 7 to a non-zero value).
These details will presumably be corrected in the next revision of
the Host Requirements specification, at which time this appendix
can be considered obsolete.
A.4 RFC-1195 (Integrated IS-IS)
Integrated IS-IS (sometimes known as Dual IS-IS) has multiple
metrics for each route. Which of the metrics is used to route a
particular IP packet is determined by the TOS field in the packet.
This is described in detail in section 3.5 of RFC-1195 [7].
The mapping from the value of the TOS field to an appropriate
Integrated IS-IS metric is described by a table in that section.
Although the specification in this memo is intended to be
substantially compatible with Integrated IS-IS, the extension of
the TOS field to four bits and the addition of a TOS value
requesting "minimize monetary cost" require minor modifications to
that table, as shown here:
The IP TOS octet is mapped onto the four available metrics as
follows:
Bits 0-2 (Precedence): (unchanged from RFC-1195)
Bits 3-6 (TOS):
0000 (all normal) Use default metric
1000 (minimize delay) Use delay metric
0100 (maximize throughput) Use default metric
0010 (maximize reliability) Use reliability metric
0001 (minimize monetary cost) Use cost metric
other Use default metric
Bit 7 (MBZ): This bit is ignored by Integrated IS-IS.
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It is expected that the next revision of the Integrated IS-IS
specification will include this corrected table, at which time
this appendix can be considered obsolete.
A.5 RFC-1247 (OSPF) and RFC-1248 (OSPF MIB)
Although the specification in this memo is intended to be
substantially compatible with OSPF, the extension of the TOS field
to four bits requires minor modifications to the section that
describes the encoding of TOS values in Link State Advertisements,
described in section 12.3 of RFC-1247 [10]. The encoding is
summarized in Table 17 of that memo; what follows is an updated
version of table 17. The numbers in the first column are decimal
integers, and the numbers in the second column are binary TOS
values:
OSPF encoding TOS
_____________________________________________
0 0000 normal service
2 0001 minimize monetary cost
4 0010 maximize reliability
6 0011
8 0100 maximize throughput
10 0101
12 0110
14 0111
16 1000 minimize delay
18 1001
20 1010
22 1011
24 1100
26 1101
28 1110
30 1111
The OSPF MIB, described in RFC-1248 [5], is entirely consistent
with this memo except for the textual comment which describes the
mapping of the old TOS flag bits into TOSType values. TOSType
values use the same encoding of TOS values as OSPF's Link State
Advertisements do, so the above table also describes the mapping
between TOSType values (the first column) and TOS field values
(the second column).
If RFC-1247 and RFC-1248 are revised in the future, it is expected
that this information will be incorporated into the revised
versions. At that time, this appendix may be considered obsolete.
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APPENDIX B. Rationale
The main body of this memo has described the details of how TOS
facility works. This appendix is for those who wonder why it works
that way.
Much of what is in this document can be explained by the simple fact
that the goal of this document is to provide a clear and complete
specification of the existing TOS facility rather than to design from
scratch a new quality of service mechanism for IP. While this memo
does amend the facility in some small and carefully considered ways
discussed below, the desirability of compatibility with existing
specifications and uses of the TOS facility [1,2,7,10,11] was never
in doubt. This goal of backwards compatibility determined the broad
outlines and many of the details of this specification.
Much of the rest of this specification was determined by two
additional goals, which were described more fully in Section 2. The
first was that hosts should never be penalized for using the TOS
facility, since that would likely ensure that it would never be
widely deployed. The second was that the specification should make
it easy, or at least possible, to define and deploy new types of
service in the future.
The three goals above did not eliminate all need for engineering
choices, however, and in a few cases the goals proved to be in
conflict with each other. The remainder of this appendix discusses
the rationale behind some of these engineering choices.
B.1 The Minimize Monetary Cost TOS Value
Because the Internet is becoming increasingly commercialized, a
number of participants in the IETF's Router Requirements Working
Group felt it would be important to have a TOS value which would
allow a user to declare that monetary cost was more important than
other qualities of the service.
There was considerable debate over what exactly this value should
mean. Some felt, for example, that the TOS value should mean
"must not cost money". This was rejected for several reasons.
Because it would request a particular level of service (cost = 0)
rather than merely requesting that some service attribute be
minimized or maximized, it would not only philosophically at odds
with the other TOS values but would require special code in both
hosts and routers. Also, it would not be helpful to users who
want their packets to travel via the least-cost path but can
accept some level of cost when necessary. Finally, since whether
any particular routing domain considers the TOS field when routing
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is a choice made by the network manager, a user requiring a free
path might not get one if the packet has to pass through a routing
domain that does not consider TOS in its routing decisions.
Some proposed a slight variant: a TOS value which would mean "I am
willing to pay money to have this packet delivered". This
proposal suffers most of the same shortcomings as the previous one
and turns out to have an additional interesting quirk: because of
the algorithms specified in Section 7.2, any packet which used
this TOS value would prefer links that cost money over equally
good free links. Thus, such a TOS value would almost be
equivalent to a "maximize monetary cost" value!
It seems likely that in the future users may need some mechanism
to express the maximum amount they are willing to pay to have a
packet delivered. However, an IP option would be a more
appropriate mechanism, since there are precedents for having IP
options that all routers are required to honor, and an IP option
could include parameters such as the maximum amount the user was
willing to pay. Thus, the TOS value defined in this memo merely
requests that the network "minimize monetary cost".
B.2 The Specification of the TOS Field
There were four goals that guided the decision to have a four bit
TOS field and the specification of that field's values:
(1) To define a new type of service requesting that the network
"minimize monetary cost"
(2) To remain as compatible as possible with existing
specifications and uses of the TOS facility
(3) To allow for the definition and deployment of new types of
service in the future
(4) To permanently fix the size of the TOS field
The last goal may seem surprising, but turns out to be necessary
for routing to work correctly when new types of service are
deployed. If routers have different ideas about the size of the
TOS field they make inconsistent decisions that may lead to
routing loops.
At first glance goals (3) and (4) seem to be pretty much mutually
exclusive. The IP header currently has only three unused bits, so
at most three new type of service bits could be defined without
resorting to the impractical step of changing the IP header
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format. Since one of them would need to be allocated to meet goal
(1), at most two bits could be reserved for new or experimental
types of service. Not only is it questionable whether two would
be enough, but it is improbable that the IETF and IAB would allow
all of the currently unused bits to be permanently reserved for
types of service which might or might or might not ever be
defined.
However, some (if not most of) the possible combinations of the
individual bits would not be useful. Clearly, setting all of the
bits would be equivalent to setting none of the bits, since
setting all of the bits would indicate that none of the types of
optimization was any more important than any of the others.
Although one could perhaps assign reasonable semantics to most
pairs of bits, it is unclear that the range of network service
provided by various paths could usefully be subdivided in so fine
a manner. If some of these non-useful combinations of bits could
be assigned to new types of service then it would be possible to
meet goal (3) and goal (4) without having to use up all of the
remaining reserved bits in the IP header. The obvious way to do
that was to change the interpretation of TOS values so that they
were integers rather than independently settable bits.
The integers were chosen to be compatible with the bit definitions
found in RFC-791. Thus, for example, setting the TOS field to
1000 (minimize delay) sets bit 3 of the Type of Service octet; bit
3 is defined as the Low Delay bit in RFC-791. This memo only
defines values which correspond to setting a single one of the
RFC-791 bits, since setting multiple TOS bits does not seem to be
a common practice. According to [15], none of the common TCP/IP
applications currently set multiple TOS bits. However, TOS values
corresponding to particular combinations of the RFC-791 bits could
be defined if and when they are determined to be useful.
The new TOS value for "minimize monetary cost" needed to be one
which would not be too terribly misconstrued by preexisting
implementations. This seemed to imply that the value should be
one which left all of the RFC-791 bits clear. That would require
expanding the TOS field, but would allow old implementations to
treat packets which request minimization of monetary cost (TOS
0001) as if they had requested the default TOS. This is not a
perfect solution since (as described above) changing the size of
the TOS field could cause routing loops if some routers were to
route based on a three bit TOS field and others were to route
based on a four bit TOS field. Fortunately, this should not be
much of a problem in practice because routers which route based on
a three bit TOS field are very rare as this is being written and
will only become more so once this specification is published.
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Because of those considerations, and also in order to allow a
reasonable number of TOS values for future definition, it seemed
desirable to expand the TOS field. That left the question of how
much to expand it. Expanding it to five bits would allow
considerable future expansion (27 new TOS values) and would be
consistent with Host Requirements, but would reduce to one the
number of reserved bits in the IP header. Expanding the TOS field
to four bits would restrict future expansion to more modest levels
(11 new TOS values), but would leave an additional IP header bit
free. The IETF's Router Requirements Working Group concluded that
a four bits wide TOS field allow enough values for future use and
that consistency with Host Requirements was inadequate
justification for unnecessarily increasing the size of the TOS
field.
B.3 The Choice of Weak TOS Routing
"Ruminations on the Next Hop" [4] describes three alternative ways
of routing based on the TOS field. Briefly, they are:
(1) Strong TOS --
a route may be used only if its TOS exactly matches the TOS
in the datagram being routed. If there is no route with the
requested TOS, the packet is discarded.
(2) Weak TOS --
like Strong TOS, except that a route with the default TOS
(0000) is used if there is no route that has the requested
TOS. If there is no route with either the requested TOS or
the default TOS, the packet is discarded.
(3) Very Weak TOS --
like Weak TOS, except that a route with the numerically
smallest TOS is used if there is no route that has either the
requested TOS or the default TOS.
This specification has adopted Weak TOS.
Strong TOS was quickly rejected. Because it requires that each
router a packet traverses have a route with the requested TOS,
packets which requested non-zero TOS values would have (at least
until the TOS facility becomes widely used) a high probability of
being discarded as undeliverable. This violates the principle
(described in Section 2) that hosts should not be penalized for
choosing non-zero TOS values.
The choice between Weak TOS and Very Weak TOS was not as
straightforward. Weak TOS was chosen because it is slightly
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RFC 1349 Type of Service July 1992
simpler to implement and because it is consistent with the OSPF
and Integrated IS-IS specifications. In addition, many dislike
Very Weak TOS because its algorithm for choosing a route when none
of the available routes have either the requested or the default
TOS cannot be justified by intuition (there is no reason to
believe that having a numerically smaller TOS makes a route
better). Since a router would need to understand the semantics of
all of the TOS values to make a more intelligent choice, there
seems to be no reasonable way to fix this particular deficiency of
Very Weak TOS.
In practice it is expected that the choice between Weak TOS and
Very Weak TOS will make little practical difference, since (except
where the network manager has intentionally set things up
otherwise) there will be a route with the default TOS to any
destination for which there is a route with any other TOS.
B.4 The Retention of Longest Match Routing
An interesting issue is how early in the route choice process TOS
should be considered. There seem to be two obvious possibilities:
(1) Find the set of routes that best match the destination
address of the packet. From among those, choose the route
which best matches the requested TOS.
(2) Find the set of routes that best match the requested TOS.
From among those, choose the route which best matches the
destination address of the packet.
The two approaches are believed to support an identical set of
routing policies. Which of the two allows the simpler
configuration and minimizes the amount of routing information that
needs to be passed around seems to depend on the topology, though
some believe that the second option has a slight edge in this
regard.
Under the first option, if the network manager neglects some
pieces of the configuration the likely consequence is that some
packets which would benefit from TOS-specific routes will be
routed as if they had requested the default TOS. Under the second
option, however, a network manager can easily (accidently)
configure things in such a way that packets which request a
certain TOS and should be delivered locally will instead follow a
default route for that TOS and be dumped into the Internet. Thus,
the first option would seem to have a slight edge with regard to
robustness in the face of errors by the network manager.
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It has been also been suggested that the first option provides the
additional benefit of allowing loop-free routing in routing
domains which contain both routers that consider TOS in their
routing decisions and routers that do not. Whether that is true
in all cases is unknown. It is certainly the case, however, that
under the second option it would not work to mix routers that
consider TOS and routers which do not in the same routing domain.
All in all, there were no truly compelling arguments for choosing
one way or the other, but it was nontheless necessary to make a
choice: if different routers were to make the choice differently,
chaos (in the form of routing loops) would result. The mechanisms
specified in this memo reflect the first option because that will
probably be more intuitive to most network managers. Internet
routing has traditionally chosen the route which best matches the
destination address, with other mechanisms serving merely as tie-
breakers. The first option is consistent with that tradition.
B.5 The Use of Destination Unreachable
Perhaps the most contentious and least defensible part of this
specification is that a packet can be discarded because the
destination is considered to be unreachable even though a packet
to the same destination but requesting a different TOS would have
been deliverable. This would seem to fall perilously close to
violating the principle that hosts should never be penalized for
requesting non-default TOS values in packets they originate.
This can happen in only three, somewhat unusual, cases:
(1) There is a route to the packet's destination which has the
TOS value requested in the packet, but the route has an
infinite metric.
(2) The only routes to the packet's destination have TOS values
other than the one requested in the packet. One of them has
the default TOS, but it has an infinite metric.
(3) The only routes to the packet's destination have TOS values
other than the one requested in the packet. None of them
have the default TOS.
It is commonly accepted that a router which has a default route
should nonetheless discard a packet if the router has a more
specific route to the destination in its forwarding table but that
route has an infinite metric. The first two cases seem to be
analogous to that rule.
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In addition, it is worth noting that, except perhaps during brief
transients resulting from topology changes, routes with infinite
metrics occur only as the result of deliberate action (or serious
error) on the part of the network manager. Thus, packets are
unlikely to be discarded unless the network manager has taken
deliberate action to cause them to be. Some people believe that
this is an important feature of the specification, allowing the
network to (for example) keep packets which have requested that
cost be minimized off of a link that is so expensive that the
network manager feels confident that the users would want their
packets to be dropped. Others (including the author of this memo)
believe that this "feature" will prove not to be useful, and that
other mechanisms may be required for access controls on links, but
couldn't justify changing this specification in the ways necessary
to eliminate the "feature".
Case (3) above is more problematic. It could have been avoided by
using Very Weak TOS, but that idea was rejected for the reasons
discussed in Appendix B.3. Some suggested that case (3) could be
fixed by relaxing longest match routing (described in Appendix
B.4), but that idea was rejected because it would add complexity
to routers without necessarily making their routing choices
particularly more intuitive. It is also worth noting that this is
another case that a network manager has to try rather hard to
create: since OSPF and Integrated IS-IS both enforce the
constraint that there must be a route with the default TOS to any
destination for which there is a route with a non-zero TOS, a
network manager would have to await the development of a new
routing protocol or create the problem with static routes. The
eventual conclusion was that any fix to case (3) was worse than
the problem.
APPENDIX C. Limitations of the TOS Mechanism
It is important to note that the TOS facility has some limitations.
Some are consequences of engineering choices made in this
specification. Others, referred to as "inherent limitations" below,
could probably not have been avoided without either replacing the TOS
facility defined in RFC-791 or accepting that things wouldn't work
right until all routers in the Internet supported the TOS facility.
C.1 Inherent Limitations
The most important of the inherent limitations is that the TOS
facility is strictly an advisory mechanism. It is not an
appropriate mechanism for requesting service guarantees. There
are two reasons why this is so:
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RFC 1349 Type of Service July 1992
(1) Not all networks will consider the value of the TOS field
when deciding how to handle and route packets. Partly this
is a transition issue: there will be a (probably lengthy)
period when some networks will use equipment that predates
this specification. Even long term, however, many networks
will not be able to provide better service by considering the
value of the TOS field. For example, the best path through a
network composed of a homogeneous collection of
interconnected LANs is probably the same for any possible TOS
value. Inside such a network, it would make little sense to
require routers and routing protocols to do the extra work
needed to consider the value of the TOS field when forwarding
packets.
(2) The TOS mechanism is not powerful enough to allow an
application to quantify the level of service it desires. For
example, an application may use the TOS field to request that
the network choose a path which maximizes throughput, but
cannot use that mechanism to say that it needs or wants a
particular number of kilobytes or megabytes per second.
Because the network cannot know what the application
requires, it would be inappropriate for the network to decide
to discard a packet which requested maximal throughput
because no "high throughput" path was available.
The inability to provide resource guarantees is a serious drawback
for certain kinds of network applications. For example, a system
using packetized voice simply creates network congestion when the
available bandwidth is inadequate to deliver intelligible speech.
Likewise, the network oughtn't even bother to deliver a voice
packet that has suffered more delay in the network than the
application can tolerate. Unfortunately, resource guarantees are
problematic in connectionless networks. Internet researchers are
actively studying this problem, and are optimistic that they will
be able to invent ways in which the Internet Architecture can
evolve to support resource guarantees while preserving the
advantages of connectionless networking.
C.2 Limitations of this Specification
There are a couple of additional limitations of the TOS facility
which are not inherent limitations but instead are consequences of
engineering choices made in this specification:
(1) Routing is not really optimal for some TOS values. This is
because optimal routing for those TOS values would require
that routing protocols be cognizant of the semantics of the
TOS values and use special algorithms to compute routes for
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RFC 1349 Type of Service July 1992
them. For example, routing protocols traditionally compute
the metric for a path by summing the costs of the individual
links that make up the path. However, to maximize
reliability, a routing protocol would instead have to compute
a metric which was the product of the probabilities of
successful delivery over each of the individual links in the
path. While this limitation is in some sense a limitation of
current routing protocols rather than of this specification,
this specification contributes to the problem by specifying
that there are a number of legal TOS values that have no
currently defined semantics.
(2) This specification assumes that network managers will do "the
right thing". If a routing domain uses TOS, the network
manager must configure the routers in such a way that a
reasonable path is chosen for each TOS. While this ought not
to be terribly difficult, a network manager could accidently
or intentionally violate our rule that using the TOS facility
should provide service at least as good as not using it.
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References
[1] Internet Engineering Task Force (R. Braden, Editor),
"Requirements for Internet Hosts -- Communication Layers", RFC
1122, USC/Information Sciences Institute, October 1989.
[2] Internet Engineering Task Force (R. Braden, Editor),
"Requirements for Internet Hosts -- Application and Support",
RFC 1123, USC/Information Sciences Institute, October 1989.
[3] Almquist, P., "Requirements for IP Routers", Work in progress.
[4] Almquist, P., "Ruminations on the Next Hop", Work in progress.
[5] Baker, F. and R. Coltun, "OSPF Version 2 Management Information
Base", RFC 1248, ACC, Computer Science Center, August 1991.
[6] Braden, R. and J. Postel, "Requirements for Internet Gateways",
RFC 1009, USC/Information Sciences Institute, June 1987.
[7] Callon, R., "Use of OSI IS-IS for Routing in TCP/IP and Dual
Environments", RFC 1195, Digital Equipment Corporation, December
1990.
[8] Deering, S., "ICMP Router Discovery Messages", RFC 1256, Xerox
PARC, September 1991.
[9] Mogul, J. and J. Postel, "Internet Standard Subnetting
Procedure", RFC 950, USC/Information Sciences Institute, August
1985.
[10] Moy, J., "OSPF Version 2", RFC 1247, Proteon, Inc., July 1991.
[11] Postel, J., "Internet Protocol", RFC 791, DARPA, September 1981.
[12] Postel, J., "Internet Control Message Protocol", RFC 792, DARPA,
September 1981.
[13] Postel, J., "Transmission Control Protocol", RFC 793, DARPA,
September 1981.
[14] Prue, W. and J. Postel, "A Queuing Algorithm to Provide Type-
of-Service for IP Links", RFC 1046, USC/Information Sciences
Institute, February 1988.
[15] Reynolds, J. and J. Postel, "Assigned Numbers", RFC 1060,
USC/Information Sciences Institute, March 1990.
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Acknowledgements
Some of the ideas presented in this memo are based on discussions
held by the IETF's Router Requirements Working Group. Much of the
specification of the treatment of Type of Service by hosts is merely
a restatement of the ideas of the IETF's former Host Requirements
Working Group, as captured in RFC-1122 and RFC-1123. The author is
indebted to John Moy and Ross Callon for their assistance and
cooperation in achieving consistency among the OSPF specification,
the Integrated IS-IS specification, and this memo.
This memo has been substantially improved as the result of thoughtful
comments from a number of reviewers, including Dave Borman, Bob
Braden, Ross Callon, Vint Cerf, Noel Chiappa, Deborah Estrin, Phill
Gross, Bob Hinden, Steve Huston, Jon Postel, Greg Vaudreuil, John
Wobus, and the Router Requirements Working Group.
The initial work on this memo was done while its author was an
employee of BARRNet. Their support is gratefully acknowledged.
Security Considerations
This memo does not explicitly discuss security issues. The author
does not believe that the specifications in this memo either weaken
or enhance the security of the IP Protocol or of the other protocols
mentioned herein.
Author's Address
Philip Almquist
214 Cole Street, Suite 2
San Francisco, CA 94117-1916
Phone: 415-752-2427
Email: almquist@Jessica.Stanford.EDU
Almquist [Page 28]